Highways Engineer

• Assist senior engineers in preparing scope of works documents and project design criteria.
• Gain experience in road design, including plans, profiles, typical sections, cross sections, and signage.
• Participate in road and highways design, including alignment, profiles, cross sections, and pavement design.
• Engage in 3D modeling and cross-section development using industry-standard software.
• Utilize PowerPoint to create presentations and progress reports.
• Demonstrate strong communication and technical report writing skills.
• Develop proficiency in road design software.
• Familiarity with engineering standards, codes of practice, and local authority guidelines is advantageous.

What We're Looking For: We are seeking a motivated graduate who:

• Is passionate about road design and engineering.
• Possesses strong communication and teamwork skills.
• Is proficient in design software or willing to learn.
• Has a keen attention to detail and a desire to deliver high-quality work.
• Has previous consultancy road design internship experience is a plus.

Qualifications
Minimum Requirements

• Bachelor’s Degree in Civil Engineering with an interest in Highways/Roads Engineering.
• Candidates must be 2024 or 2023 recent graduates, to be eligible for AECOM's Graduate Program.
• Must have a minimum 2.8 GPA and above.
• Immediately available to join by March 2025.
• A strong desire to learn, grow, and contribute to AECOM's Emiratisation efforts through our Fursa Program.

1. Technical Knowledge of Highway Design

• Road Geometry Design: Knowledge of geometric design principles, including alignment, cross-section, gradients, and curve radii.
• Pavement Design: Understanding the design and construction of different pavement types (flexible, rigid, or composite) based on soil, traffic load, and climate conditions.
• Drainage Design: Expertise in designing effective stormwater drainage systems for highways to prevent flooding and erosion.
• Traffic Engineering: Knowledge of traffic flow principles, intersection design, traffic signal systems, and vehicular safety.

2. Traffic Analysis and Modeling

• Using software tools to model and analyze traffic patterns (e.g., VISSIM, SIDRA, HCS).
• Conducting traffic surveys, analyzing vehicle flow, congestion, and safety issues.
• Understanding traffic forecasting and capacity analysis techniques.

3. Geotechnical Engineering

• Understanding soil mechanics and geology to assess the suitability of materials for road construction.
• Evaluating soil stability, compaction, and the need for stabilization methods.

4. Knowledge of Highway Safety

• Designing roads that enhance safety for vehicles and pedestrians, including safety barriers, guardrails, signage, and road markings.
• Familiarity with road safety audits and crash data analysis to improve road conditions and minimize accidents.
• Analyzing potential hazards such as blind spots, sharp turns, and dangerous intersections.

5. Construction and Materials Engineering

• Understanding construction techniques, such as road paving, grading, and embankment formation.
• Knowledge of construction materials (asphalt, concrete, aggregates, etc.) and their properties, as well as their suitability for different conditions.
• Familiarity with materials testing, such as compaction and density testing.

6. Regulatory and Standards Knowledge

• Familiarity with national and international design standards, such as those from AASHTO (American Association of State Highway and Transportation Officials) or ISO standards.
• Knowledge of local building codes, zoning regulations, and environmental compliance requirements for highway projects.
• Understanding of legal considerations, including right-of-way acquisition, permits, and environmental impact assessments (EIA).

7. Environmental Considerations

• Awareness of the environmental impacts of highway projects and design strategies to minimize harm (e.g., noise, air pollution, wildlife protection).
• Understanding of sustainable practices in highway construction, such as using recycled materials or reducing the carbon footprint of transportation infrastructure.
• Designing mitigation measures for projects in environmentally sensitive areas, such as wetlands, wildlife corridors, and protected landscapes.